MD results from Nov. 20 on low transition energy in the SPS and studies for 2011

1. MD results from Nov. 20 on low transition energy in the SPS and studies for 2011 H. Bartosik, Y. Papaphilippou, B. Salvant, T. Argyropoulos

2. Motivation for lower transition energy • Instability thresholds for TMCI and longitudinal instabilities increase linearly with slippage factor η • Higher slippage factor means more mixing in longitudinal plane and faster damping • Higher instability thresholds is thus expected for lower transition energies γt (=higher slippage factor) • Lower γt can be achieved in SPS easily by reducing the horizontal betatron tune • Nominal working point for LHC beams (Q26): Qx=26.13, Qy=26.18, yt=22.8, η(@26GeV)=0.63E-3, maximal horizontal dispersion~4.8m • New working point for LHC beams (Q20): Qx=20.13, Qy=20.18, yt=18, η(@26GeV)=1.8E-3, maximal horizontal dispersion~8m • Increase of η by a factor of 2.8 @injection and 1.6 @extraction! • Possible limitation: for achieving same longitudinal parameters (bucket area) RF-voltage needs to be increased according to V~η • However, smaller longitudinal emittance blow-up for same stability

3. Previous results • 2 cycles with lower γt (Q20) prepared in the SPS database • MD1 for flat bottom studies (3.7s) • LHCfast3 with acceleration up to 450GeV • Transfer lines TT2/TT10 not matched to new optics yet • Optics function in the new cycles confirmed by measurements • Experimentally confirmed increase of slippage factor by measurement of synchrotron frequencies for nominal and new optics • Up to now studies with single bunches only • Successfully injected up to 3.3E11 p/bwith MD1 cycle • Successfully accelerated up to 2.5E11 p/b up to 450GeV • No significant blow-up of transverse emittances observed • Higher thresholds for Transverse Mode Coupling (TMC) instabilities qualitatively confirmed • Particle losses (~10%) within the first 10ms after injection of about 3E11 p/b for RF-voltage of 1.8MV (measured with the integrated bunch intensity from the wall current monitor)

4. Losses at injection for different RF-voltages • Scan of RF-voltage for different intensities • Qx=20.13, Qy=20.18, ξx~0.2, ξy~0.03 (chromaticities not measured) • Improving losses within 10 ms after injection by increasing RF-voltage • Small effect for intensity around 1E11 p/b: 2-4% losses • Losses of around 4% for RF-voltage above 2.5 MV for 2E11, but increased loses for lower voltages • No clear dependence on RF-voltage in both cases (for RF voltage above 2.5MV)maybe due to longitudinal phase space distribution coming from the PS or space charge effects (optimization for high intensities needed)

5. Intensity along flat bottom of MD1 RF-voltage: 1.8 MV RF-voltage: 3.2 MV RF-voltage: 3.8 MV • Immediate losses with 1.8 MV (~10%) • Reduced losses within first 20 ms after injection for RF-voltage above 2.5 MV (~4%) • Slow losses within 1.5 s • Total losses seem to increase again with higher voltage – Crossing of resonances due to increased space charge forces arising from shorter bunch length? • Comparison with nominal Q26 MD1 cycle and further studies needed

6. To be addressed next year Correct chromaticity along the acceleration cycle for providing comparable set of machine parameters Optimize RF parameters at flat bottom and along the cycle Study longitudinal parameters at 450 GeV for different intensities – compatible with LHC requirements and available RF-voltage? Investigate loss mechanisms at injection – optimize working point and further studies on the nonlinear machine model (space charge, resonances, …) Inject LHC bunch trains with high intensity for studying impact on electron cloud and other multi-bunch instabilities with all different bunch spacings Investigate the possibility of injecting high intensity (CNGS) beams above transition (Q15) Q20 cycles could be very useful to study the localization of impedance sources of the machine Match transferline TT2/TT10

7. Possible simulation studies • Study space charge effects and find improved nonlinear model for optimizing working pointfor new optics with different emittances: Hannes • Study electron cloud instability with new optics with different bunch spacings: Kevin • “Headtail” simulations on Transverse Mode Coupling instabilities for estimating thresholds for nominal and new optics (injection/extraction): Benoit • Study of the impedance localization through intensity dependent multi-BPM response (cross check with one-turn transfer matrix): Nicolo • Study coupled bunch instabilities (transverse, injection/extraction): Nicolas • Studies in longitudinal plane: Elena S./Theodoros/Chandra • Coupled bunch instabilities (injection-extraction) • Double RF – use of 800MHz cavity and longitudinal emittance blow-up • Matching of transfer line TT2/TT10: Elena B./Hannes